UMLS:C0006826 - FACTA Search

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Query: UMLS:C0006826 (cancer)
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A putative tumor suppressor gene, p16 (MST1; multiple tumor suppressor 1/CDK4I; cyclin-dependent kinase 4 inhibitor), was isolated and mapped on the short arm of chromosome 9 (9p). The significance of p16 mutations in gastric tumorigenesis was examined by assessing p16 mutations as well as loss of heterozygosity (LOH) on 9p in 13 gastric adenomas and 45 adenocarcinomas. LOH on 9p (IFNA; alpha-interferon locus) was detected in 22% (5/23 informative cases) of differentiated adenocarcinomas, 10% (1/10) of undifferentiated carcinomas and none (0/6) of the adenomas. Although we found a sequence polymorphism at the second position of codon 99 (CGC/CAC) of the p16 in one gastric adenoma patient, no somatic mutations were detected in any of the gastric adenomas or adenocarcinomas. These results suggest that p16 mutations probably do not contribute to gastric tumorigenesis. However, these data suggest that another tumor suppressor gene on 9p (near the IFNA locus) may contribute to the progression of differentiated adenocarcinoma of the stomach.
Jpn J Cancer Res 1995 Apr
PMID:Loss of heterozygosity on the short arm of chromosome 9 without p16 gene mutation in gastric carcinomas. 777 54

Sporadic and familial malignant melanoma susceptibility has been linked to defects in the chromosomal region 9p21. Recently, a putative 9p21 tumor suppressor gene, the cyclin dependent kinase inhibitor 2 (CDKN2) or p16 gene, has been shown to be deleted, mutated, or rearranged in a high percentage of sporadic melanoma cell lines, as well as mutated in the germline of a proportion of familial melanoma patients. CDKN2 encodes a M(r) 16,000 protein (p16) that plays a key role in cell cycle control by binding to the cyclin-dependent kinase 4 enzyme and inhibiting its ability to phosphorylate critical substrates necessary for transition past the G1 phase of the cell cycle. Thus, mutations or deletions of the CDKN2 gene could result in abnormal proliferation via defective cell cycle control. The correlation of 9p21 cytogenetic and molecular alterations with the clinical stages of melanoma progression suggests that dysfunction of a gene within this chromosomal region is critical to the evolution of melanoma. However, it remains unclear whether this gene is the CDKN2 gene. If so, then loss of p16 is potentially an initiating or early event in melanoma progression. To address the issues of what is the potential involvement of the CDKN2 gene in sporadic melanoma and precisely when during the clinically evident stages of melanoma progression defects in CDKN2 occur, we have evaluated by immunohistochemistry the expression of p16 protein in 103 melanocytic lesions representing all stages in the progression of melanoma. Our results suggest that loss of p16 protein expression is (a) not necessary for tumor initiation in malignant melanoma because all melanomas in situ and the majority of primary invasive melanomas retain expression of this protein; and (b) potentially more related to invasiveness or the ability to metastasize, because 52% of primary invasive tumors and 72% of metastatic lesions show partial or complete loss of expression of p16.
Cancer Res 1995 Jul 01
PMID:Loss of expression of the p16/cyclin-dependent kinase inhibitor 2 tumor suppressor gene in melanocytic lesions correlates with invasive stage of tumor progression. 779 91

To define the extent of involvement of chromosome 9p in breast carcinogenesis, we performed microsatellite length polymorphism analysis of markers spanning this region. Of 24 primary breast carcinomas analyzed, we observed a high frequency (58%) of loss of heterozygosity or allelic imbalance affecting subregion 9p21-22. Mutational analysis of CDKN2 (p16) was performed to determine whether this gene was the target of such alterations. Of 21 tumors analyzed, only 1 showed a mutation of probable consequence, suggesting that CDKN2 appears not to be the target of loss of heterozygosity and indicating the possible existence of another tumor suppressor gene within this region. Additionally, since it has been suggested that some CDKN2 deletions and mutations could be due to an in vitro phenomenon, four immortal breast cell lines derived from normal epithelium, MCF10F, MCF12F, 184A1, and 184B5, were examined for loss or mutation of CDKN2. Two lines (MCF10F and MCF12F) showed homozygous deletions of CDKN2, and one (184A1) revealed a hemizygous deletion and a nonsense mutation in the remaining allele. This could imply an important role of CDKN2 in the control of immortalization or in vitro adaptation and is the first evidence of such in nontumor-derived cell lines. Additionally, this is the first report of frequent loss of heterozygosity in the 9p21-22 chromosome subregion of uncultured primary breast tumors.
Cancer Res 1995 Jul 01
PMID:Chromosome 9p allelic loss and p16/CDKN2 in breast cancer and evidence of p16 inactivation in immortal breast epithelial cells. 779 17

To investigate the potential loss of tumor suppressor gene loci on chromosome 9 in human renal cell tumorigenesis we analyzed 42 paired normal and tumor DNAs with 18 polymorphic microsatellite markers spanning this chromosome. Fourteen of 42 (33%) tumors showed partial or complete deletion of chromosome 9. Deletion mapping provided evidence for the presence of a suppressor locus on both the short and long arm of chromosome 9. Homozygous deletion at 9p21-22 in one renal tumor and a selective deletion of distal 9q in another tumor localized the critical regions. The CDKN2/p16 gene was further investigated as a candidate suppressor locus on 9p21-22 by multiplex PCR, Southern analysis, and exon sequencing. We found no additional cases of homozygous deletion nor any rearrangements or point mutations of CDKN2/p16. This is the first report of 9p loss of heterozygosity, homozygous deletion of 9p21-22 and selective deletion of 9q in primary renal cell carcinomas. Understanding the molecular genetic basis of renal cell progression will require the isolation and characterization of additional tumor suppressor genes on chromosome 9.
Cancer Res 1995 Jan 15
PMID:Localization of tumor suppressor loci on chromosome 9 in primary human renal cell carcinomas. 781 48

The p16 protein is a cyclin inhibitor encoded by a gene located in 9p21, which may have antioncogenic properties, and is inactivated by homozygous p16 gene deletion or, less often, point mutation in several types of solid tumors often associated to cytogenetic evidence of 9p21 deletion. We looked for homozygous deletion and point mutation of the p16 gene in acute lymphoblastic leukemia (ALL), where 9p21 deletion or rearrangement are also nonrandom cytogenetic findings. Other hematologic malignancies including acute myeloid leukemia (AML), myelodysplastic syndromes (MDS), chronic lymphocytic leukemia (CLL), and myeloma were also studied. Homozygous deletion of the p16 gene was seen in 9 of the 63 (14%) ALL analyzed, including 6/39 precursor B-ALL, 3/12 T-ALL, and 0/12 Burkitt's ALL. Three of the 7 ALL with 9p rearrangement (including 3 of the 5 patients where this rearrangement was clearly associated to 9p21 monosomy) had homozygous deletion compared to 5 of the 55 patients with normal 9p (the last patient with homozygous deletion was not successfully karyotyped). Single stranded conformation polymorphism analysis of exons 1 and 2 of the p16 gene was performed in 88 cases of ALL, including the 63 patients analyzed by Southern blot. Twenty-six of the cases had 9p rearrangement, associated to 9p21 monosomy in at least 12 cases. A missense point mutation, at codon 49 (nucleotide 164), was seen in only 1 of the 88 patients. No homozygous deletion and no point mutation of the p16 gene was seen in AML, MDS, CLL, and myeloma. Homozygous deletion of interferon alpha genes (situated close to p16 gene in 9p21) was seen in only 3 of the 9 ALL patients with p16 gene homozygous deletion, and none of the ALL without p16 gene homozygous deletion. Our findings suggest that homozygous deletion of the p16 gene is seen in about 15% of ALL cases, is not restricted to cases with cytogenetically detectable 9p deletion, and could have a pathogenetic role in this malignancy. On the other hand, p16 point mutations are very rare in ALL, and we found no p16 homozygous deletions or mutations in the other hematologic malignancies studied.
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PMID:p16 gene homozygous deletions in acute lymphoblastic leukemia. 783 69

The CDKN2 (MTS1) gene is located at 9p21; its product, p16, inhibits the cyclin D/CDK4 complex that phosphorylates pRb, thus negatively regulating cell cycle progression [M. Serrano et al., Nature (Lond.), 366: 704, 1994; A. Kamb et al., Science (Washington DC), 264: 436, 1994; T. Nobori et al., Nature (Lond.), 368: 753, 1994]. CDKN2 mutations are more common in cultured human uroepithelial cells (HUC) than in uncultured bladder cancers. We examined the status of CDKN2/p16 in early and late passage (P) cultures of HUC. HUC immortalization was not accompanied by p16 loss, even in cells with a hemizygous 9p21-pter deletion, but late passage cultures with a p16 loss showed decreased generation time. Thus, the data do not indicate that CDKN2 is a candidate for a chromosome 9 senescence gene but suggest that p16 loss may confer a growth advantage in vitro. Significant differences in p16 levels were observed among HUC cell lines, but no CDKN2 mutations were detected. However, an inverse correlation between elevated p16 and loss of pRb function was observed (P < 10(-4)). Ten samples with normal pRb showed low or undetectable p16 levels, while seven samples with known pRb alterations showed abundant p16 but nevertheless grew vigorously in culture. These results support the hypothesis that p16 mediated cell cycle inhibition, as well as p16 regulation, occurs via pRb dependent pathway(s).
Cancer Res 1995 Feb 01
PMID:Increased p16 levels correlate with pRb alterations in human urothelial cells. 783 15

cdk4-mediated phosphorylation of the retinoblastoma susceptibility protein (Rb) is stimulated by cyclin D1, an oncogene, and inhibited by p16, a candidate tumor suppressor. We examined these proteins in non-small cell lung cancer (NSCLC), which is predominantly Rb positive, and small cell lung cancer (SCLC), which is Rb negative. Most NSCLC and SCLC resection specimens and cell lines overexpress cyclin D1 (indicating that cyclin D1 overexpression and Rb inactivation can coexist in SCLC). However, 9 of 9 Rb-positive NSCLC cell lines have absent or low p16, while an Rb-negative NSCLC line and 5 of 5 SCLC cell lines have high levels of p16. In primary resection specimens, p16 was undetectable in 18 of 27 NSCLC samples and abundant in 4 of 5 SCLC samples. Our data confirm the predicted reciprocity between Rb inactivation and p16 expression in a common human malignancy and define differential p16 expression as a fundamental distinction between NSCLC and SCLC.
Cancer Res 1995 Feb 01
PMID:Reciprocal Rb inactivation and p16INK4 expression in primary lung cancers and cell lines. 783 18

Frequent homozygous deletions of the p16 (MTS1) gene encoding a cyclin-dependent kinase inhibitor were recently reported in various tumor cell lines including examples derived from lung cancers, but direct evidence for their occurrence in lung cancer patients has not been reported thus far. In the present study, alterations of p16 and/or p15, a p16-related cyclin-dependent kinase, were observed not only in lung cancer cell lines but also in the corresponding tumor specimens in vivo, excluding the possibility of in vitro artifacts. Interestingly, a clear specificity was also noted in terms of the affected histological subtype; i.e., only non-small cell lung cancers carried alterations (6 of 20 as compared to 0 of 20 small cell lung cancer cell lines).
Cancer Res 1995 Feb 01
PMID:In vivo occurrence of p16 (MTS1) and p15 (MTS2) alterations preferentially in non-small cell lung cancers. 783 19

MTS-1 is a candidate tumor suppressor gene on chromosome 9p21-22, a region frequently observed to have loss of heterozygosity in esophagus squamous cell carcinomas and pancreatic ductal adenocarcinomas. In order to determine whether MTS-1 sequences are deleted or mutated in cell lines derived from these cancers, we performed PCR amplification of MTS-1 exons 1 and 2. In this fashion, we found that 67% of esophagus squamous cancer cell lines have deletions of both exons 1 and 2, and 50% of pancreatic cancer cell lines have similar deletions. Furthermore, an additional 30% of pancreatic cancer cell lines harbored point mutations or microdeletions based on DNA sequencing. MTS-1 encodes p16, an inhibitor of cyclin-dependent kinase 4 (cdk4) which complexes with cyclin D1. Our data suggest that MTS-1 deletions and mutations may play an important role in the molecular pathogenesis of esophagus squamous cell and pancreatic cancers.
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PMID:MTS-1 (CDKN2) tumor suppressor gene deletions are a frequent event in esophagus squamous cancer and pancreatic adenocarcinoma cell lines. 784 88

D-type cyclins are proto-oncogenic cell cycle regulators implicated in the pathogenesis of several types of cancer. Amplification of the cyclin D1 gene has been described in 30-50% of human head and neck squamous cell carcinoma (HNSCC). Using immunohistochemistry on archival specimens of human HNSCC and a mAb DCS-6, which is specific for cyclin D1, strong positivity was found in nuclei of 9 (17%) of 52, a moderately elevated signal in 16 (31%) of 52, and weak staining comparable with normal tissues in 27 (52%) of 52 patients. Immunoblotting analysis of five HNSCC-derived cell lines showed three distinct spectra of D-type cyclin proteins: cyclin D1 only (in UMSCC-2 and UMSCC-22b cell lines with 11q13 amplification), cyclins D1 and D3 (in HN5 and HN6), or cyclins D1, D2, and D3 (in UMSCC-1). Electroporation of neutralizing antibodies demonstrated requirement for cyclin D1 in cell cycle progression of all five HNSCC cell lines. Cyclin D2 was essential and showed a cooperative effect with cyclin D1 in positive regulation of G1 in UMSCC-1 cells. These data are consistent with the proposed oncogenic role of cyclin D1 in HNSCC and open up the way for immunohistochemical assessment of cyclin D1 aberrations in archival clinical specimens. It is also suggested that excessive levels of cyclin D1 alone or cooperative effects of several D-type cyclin proteins may lead to deregulation of G1 control in distinct subsets of human HNSCC. These results are discussed in the context of possible functional redundancy of D-type cyclins and the role of the D-type cyclin/p16-CDKN2/pRB pathway in tumorigenesis.
Cancer Res 1995 Feb 15
PMID:Abnormal patterns of D-type cyclin expression and G1 regulation in human head and neck cancer. 785 Aug 12

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